| 1st | ||
|---|---|---|
| Major Required | Engineering Design Practice | Time to learn surface modeling and dynamic assembly with Creo, and time to calculate the force and speed of each part using ANSYS. The goal is to design and analyze assembly mechanisms. |
| Machine element design | It is a course to learn the basic contents of mechanical design. It has the time to design various mechanical elements such as shaft, key, bearing, and gear from the selection of materials and to design directly through the project. | |
| System Modeling and Control | Based on the basic theory of control, it is a course to learn dynamic system modeling in time and frequency domain, time response analysis and stability. Includes one hour of control exercises. | |
| Mechanical Engineering Experiments (I) | It is a subject that can practice CNC machining, milling, lathe, welding, heat treatment, casting and various measurement methods directly based on the theoretical concept of machine tool learned in second year 2nd. Students will learn advanced data processing, digital I / O, and signal conversion with advanced computer interface technology, and have time to design real machines through projects. | |
| Major Elective | Engineering Statistics | This course is to learn about probability and statistics such as random variables, probability density function, discrete probability distribution, continuous probability distribution, mean, variance, binomial distribution and application of them. |
| Undergraduate Independent Studies (II) | This class is designed with the goal of visiting individual laboratories operated by the Faculty of Mechanical Engineering and learning about the research conducted in each laboratory. You will be given the opportunity to visit more than 30 graduate laboratories, and learn about the academic application of mechanical engineering through research introduction, professor introduction, and field introduction. | |
| Mechanical Vibration | Based on fundamental vibration analysis method of mechanical system, it learns free vibration of one degree of freedom system, forced vibration, vibration analysis of multi degree of freedom system, and vibration analysis of continuous system. | |
| Future Power Train Engineering | This course introduces the fundamentals of internal combustion engines and advanced powertrain systems, covering performance, efficiency, emissions, and future technologies such as batteries and fuel cells with a focus on thermal-fluid aspects. | |
| Applied Fluid Mechanics | With the deepening of fluid dynamics, we aim to learn a variety of methods to solve real fluid flow problems, including internal and external flows, using mathematical and experimental methods. | |
| Firing Process Analysis | Definition of plasticity, relationship between stress and strain, basic contents, slab analysis, up-scale analysis, energy analysis, etc. | |
| Micro Nano Engineering | The course is divided into two areas, micro / nano. This course introduces micro / nano technology and introduces design, processing, energy technology and various application technologies. | |
| Introduction to Radiation Engineering | This course introduces the concepts and applications of radiation engineering. You can learn nuclear reactions, radiation, radiation interaction with matter, and radiation detection principles. | |
| 2nd | ||
| Major Required | Product Development Design | It is a subject that defines a design problem and carries out a project to solve it. It is divided into lecture time to learn design principles to manage project and design time to directly experience whole project. |
| Mechanical Engineering Experiments (II) | This course aims to develop practical understanding and application skills of basic concepts and theories of mechanical engineering through 12 thematic experiments. You will also learn teamwork and report writing skills. | |
| Major Elective | APPLICATIONS OF ENGINEERING DESIGN | This course is an advanced practice of ANSYS in engineering design, focusing on performing and analyzing nonlinear structural analysis. To this end, students will learn using Computational Fluid Dynamics (CFD) simulations and Ansys WorkBench. |
| Mechanical System Design | It is an intensive course in mechanical element design. It has a project time to learn various mechanical elements such as belts, chains, brakes, screws and welding, and to design mechanical systems based on them. | |
| Artificial Intelligence for Mechanical Engineering | This course introduces essential AI techniques for mechanical engineering, covering regression analysis, classification, decision trees, and random forests. Students will learn how to apply these methods to engineering problems from both theoretical and practical implementation perspectives. In the latter part of the course, the class explores deep learning models such as neural networks, CNNs, RNNs, and LSTMs, and studies how to apply them to the field of mechanical engineering. | |
| Heat Transfer | This course is to acquaint students with the basic concepts of conduction, convection and radiation, which are three types of heat transfer, as well as detailed theories on steady-state conduction heat transfer, external and internal convection heat transfer. | |
| Machining system | Based on the introduction of the machining process system, it is a subject to learn the principle, structure and characteristics of various machine tools. You can also learn about automation and design of machine tools. | |
| Control system | System modeling and control are intensified contents. It is divided into lecture time and practice time for implementation and verification of theoretical content. Students learn about modeling and control of dynamic systems as well as various digital control methods. | |
| Production System Engineering | Based on the basic concept and structure of the production system, it is the course to learn the production planning and scheduling of material flow, product planning, process planning and various production systems currently provided. | |
| Automotive Engineering | It is Team-Teaching lesson that 4 professors of each field are dead. You can learn four topics: structure, control, power and materials. | |
| Reactor theory | We emphasize the physical phenomena of nuclear reactors and aim to introduce them to reactor theory. Basic physics related to nuclear reactors, interaction of neutrons with matter, and static / transient phenomena of reactors. | |
| Radiation Health Physics | Learn about physical measurements of various types of radiation and radioactive materials, establishing quantitative relationships between radiation exposure and biological damage, radioactive transport through the environment, radiologically safe equipment, process and environment design. | |